Seroepidemiological study of Q fever in domestic ruminants in semi-extensive grazing systems
© Ruiz-Fons et al; licensee BioMed Central Ltd. 2010
Received: 4 September 2009
Accepted: 20 January 2010
Published: 20 January 2010
Q fever, a worldwide zoonotic disease caused by Coxiella burnetii, is endemic in northern Spain where it has been reported as responsible for large series of human pneumonia cases and domestic ruminants' reproductive disorders. To investigate pathogen exposure among domestic ruminants in semi-extensive grazing systems in northern Spain, a serosurvey was carried out in 1,379 sheep (42 flocks), 626 beef cattle (46 herds) and 115 goats (11 herds). Serum antibodies were analysed by ELISA and positive samples were retested by Complement Fixation test (CFT) to detect recent infections.
ELISA anti-C. burnetii antibody prevalence was slightly higher in sheep (11.8 ± 2.0%) than in goats (8.7 ± 5.9%) and beef cattle (6.7 ± 2.0%). Herd prevalence was 74% for ovine, 45% for goat and 43% for bovine. Twenty-one percent of sheep flocks, 27% of goat and 14% of cattle herds had a C. burnetii seroprevalence ≥ 20%. Only 15 out of 214 ELISA-positive animals reacted positive by CFT. Age-associated seroprevalence differed between ruminant species with a general increasing pattern with age. No evidence of correlation between abortion history and seroprevalence rates was observed despite the known abortifacient nature of C. burnetii in domestic ruminants.
Results reported herein showed that sheep had the highest contact rate with C. burnetii in the region but also that cattle and goats should not be neglected as part of the domestic cycle of C. burnetii. This work reports basic epidemiologic patterns of C. burnetii in semi-extensive grazed domestic ruminants which, together with the relevant role of C. burnetii as a zoonotic and abortifacient agent, makes these results to concern both Public and Animal Health Authorities.
Q fever is a worldwide distributed zoonosis caused by Coxiella burnetii, a ubiquitous Gram-negative bacterium that is able to infect humans and a wide range of animals, both aquatic and terrestrial [1–3]. Q fever is a polymorphic disease in humans with subclinic, acute and chronic forms [1, 3]. Several groups in Spain have studied the clinical aspects and the distribution of the disease in different regions [5–7]. The disease seems to be more prevalent in northern Spain than in the central and southern regions of the country, and it is especially high in the Basque Country (northern Spain) where large series of human pneumonia cases due to C. burnetii have been reported [1, 8]. It is proposed that C. burnetii is maintained in nature following two different cycles, the wild cycle in which ticks and wild animals are involved, and the domestic cycle, where ruminant and other animal species such as dogs and cats are the main reservoirs [1, 3]. Nonetheless, the link between both proposed cycles is currently weakly known, especially because the domestic cycle has been considered the main source for human infection  and has therefore been the focus of most studies.
Clinical outcome of C. burnetii infection in domestic ruminants consists of abortion and stillbirths in sheep and goats while it causes infertility and mastitis in cattle . No clinical signs are evidenced in non-pregnant animals. When abortion occurs, or even when ewes lamb normally, animals shed a high number of C. burnetii through placenta, vaginal fluids, faeces and milk [1, 11, 12]. Infectious abortion in domestic ruminants is a multi-etiologic process that causes important losses in the livestock industry. Furthermore, the zoonotic nature of most of the abortifacient pathogens is a cause for concern from the perspective of Public Health. While attention has been paid to most of these pathogens, such as Brucella, Chlamydophila or Toxoplasma in sheep, others like C. burnetii have not been routinely investigated in cases of abortion. The recent application of molecular techniques to study fetal tissues and placenta indicates that C. burnetii could be more prevalent than previously thought [13, 14].
Serological surveys have been carried out in many countries to evaluate the distribution of C. burnetii in domestic ruminants. In some areas bovine seems to be the main reservoir [15–17] whereas in others, goats [18, 19] or sheep [20–22] are the main domestic reservoir. However in other studies, serological surveys indicate that the different domestic ruminant species can play together a relevant role in the domestic cycle of C. burnetii [3, 23–25]. In addition, different management systems showed different degree of exposure to infection . Regarding Spain, few serological evidences have been reported both in domestic and wild ruminants [5, 27].
Under the current panorama of Q fever re-emergence and the lack of information on the current status of C. burnetii infection in domestic ruminants in one of the most traditional livestock producing regions in Spain, we aimed to determine the epidemiological situation of this pathogen in the framework of a larger project on coxiellosis in livestock and wildlife. This study updates the status of this zoonotic pathogen in the ruminants population of the Basque Country and highlights the main risks for human infection in a hyperendemic Q fever region. We also evaluated if the age of the animals might account for differences in exposure to C. burnetii. Moreover, relationships between C. burnetii contact rate and abortion history at the herd level were also investigated.
The survey was carried out from October 2007 to April 2008. Overall regional census was compiled for each ruminant species (data from the Basque Statistics Institute) and sample size was proportionally calculated according to the number of herds per county with a maximum number of 2,000 animals from 100 herds. Individuals (females) older than one year were randomly selected within herds to a maximum of 30 sheep, 15 beef cattle and 10 goats per herd. Finally, 1,379 sheep, 626 beef cattle and 115 goats from 46, 42 and 11 herds, respectively, were surveyed (Figure 1). Whole blood extractions were carried out by the veterinary practitioner groups in charge of the Official Sanitary Campaigns in the Basque Country, directed and supervised by the local Animal Health and Welfare Authorities (Diputaciones Forales).
After individual collection of blood into tubes without anticoagulant, sera were obtained by centrifugation and stored at -20°C until serological analyses were performed. History of recent abortion (i.e., occurrence of abortions during the two previous breeding seasons) was obtained from a number of the surveyed herds by interviewing the farmers during sample collection.
Sera were tested for the presence of anti-C. burnetii antibodies by means of an ELISA test (ELISA Cox kit, LSI-Laboratoire Service International, Lyon, France) according to manufacturer's instructions. Sensitivity of this ELISA test reaches 100% whereas specificity was determined to be of 95% (manufacturer's data). ELISA positive sera were retested for anti-C. burnetii antibodies by means of the Complement Fixation test (CFT) following standard procedures . C. burnetii antigen was provided by Dade Behring (Marburg, Germany) using Nine Mile and Henzerling strains produced on embryonated eggs. According to the standards of the OIE, samples with CFT titres ≤ 1/5 were considered negative. Titres between 1/10 and 1/40 were representative for latent infection while titres ≥ 1/80 revealed an evolutive phase of the infection .
Mean anti-C. burnetii antibody prevalence (Serop.) and its associated standard error (SE) throughout ruminant species-by-age class.
ELISA anti-C. burnetii antibody prevalence was calculated at individual and at herd level for each ruminant species. Rogan-Gladen correction (RGC) according to the sensitivity and specificity of the ELISA test was used for population seroprevalence calculation . A herd was considered positive when at least one animal showed antibodies by ELISA. Thus, differences on antibody prevalence (continuous) between ruminant species, age classes (categorical) and abortion history (categorical, reported/non-reported) were statistically assessed by means of Chi-square tests. Statistical uncertainty was assessed by calculating the 95% confidence interval for each of the proportions according to the expression S.E.95%C.I. = 1.96 [p(1 - p)/n]1/2 .
ELISA test showed an average C. burnetii seroprevalence of 11.8 ± 2.0% (RGC: 7.1 ± 1.4%) in sheep, 8.7 ± 5.9% (RGC: 3.9 ± 3.5%) in goats and 6.7 ± 2.0% (RGC: 1.8 ± 1.0%) in beef cattle. Statistically significant differences were found between cattle and sheep seroprevalences (χ2 = 11.7, p < 0.001). The percentage of seropositive herds was 74% (34/46) for sheep, 43% (18/42) for cattle and 45% (5/11) for goats. Within-herd seroprevalence values ranged 0-80% for sheep, 0-53% for cattle and 0-30% for goats, with 21%, 14% and 27% of the herds, respectively, showing a C. burnetii seroprevalence ≥ 20%.
Eight out of 162 (4.9 ± 3.3%), 6 out of 42 (14.3 ± 10.6%) and 1 out of 10 (10.0 ± 18.6%) ELISA-positive sheep, cattle and goats, respectively, also reacted positive in the CFT giving titres ≥ 1/10. CFT positive ewes belonged to 5 herds (5/46, 8.7%) and antibody titres did not exceed 1/20. In cattle, CFT positive animals belonged to 3 herds (3/42, 7.1%) and antibody titres did not exceed 1/40. Finally, only one goat reacting positive in ELISA also reacted in the CFT showing a titre of 1/10.
ELISA seroprevalence-age associated patterns differed between ruminant species (Table 1). While C. burnetii seroprevalence tended to increase from yearlings to adults in sheep and goats, seroprevalence values remained similar for heifer and adult cattle. Nonetheless, no statistically significant differences between age class seroprevalence values were found. In addition, anti-C. burnetii antibody prevalence did not differ statistically in relation to herd abortion history, neither in sheep (9.1 ± 3.9% for flocks reporting abortion and 9.0 ± 2.0% for non-reporting flocks) nor in cattle (10.7 ± 7.8% and 9.4 ± 3.9%, respectively). Seven of the 23 interviewed sheep flock owners reported recent problems of abortion. Five of these flocks were positive for ELISA anti-C. burnetii antibodies, with seroprevalences ranging between 3.3% and 36.7%. Interestingly, CFT titres ≥ 1/10 were detected in only one of those flocks. Meanwhile, 5 of 18 cattle herds reported abortion problems and showed seroprevalences between 0% and 20%, but none of the ELISA positive animals from those herds reporting abortion had significant CFT titres. Conversely, 6 of 13 cattle herds reporting no reproductive problems showed seroprevalences between 6.6% and 53.3% by ELISA, and in 2 of these herds several animals showed titres ≥ 1/10 against Coxiella by CFT. Recent abortion history could only be obtained from a small number of goat herds (n = 4) and consequently we did not considered them in the analysis.
Q fever is considered a strongly endemic disease in humans in the Basque Country [32, 33]. Contact with domestic ruminants was considered one of the most relevant risk factors for C. burnetii infection. Moreover, C. burnetti was found to be widespread in sheep flocks  and is known to be a relevant agent for ovine abortion  that causes important economic losses to livestock producers. Nevertheless, very scarce information on the current status of this pathogen in other ruminant species, such as cattle or goats, was available for this region. As a first approach to improve knowledge on the current status of C. burnetii among livestock in the Basque Country, we studied the seroprevalence in beef cattle, sheep and goats, which are reared in semi-extensive conditions, while intensively managed species (dairy cattle) will be the subject of a future study.
Comparison of herein reported ELISA results with other epidemiological surveys has to be carefully considered due to the different serological techniques employed. While recent studies tend to use the indirect fluorescence assay (IFA) or ELISA, those carried out some decades ago used mainly CFT. Whereas IFA and ELISA tests on ruminant sera showed similar results, low agreement was observed between ELISA and CFT [35, 36], which agrees with our observations in sheep (unpublished data). CFT has a good specificity but a low sensitivity ; in fact, only 15 out of 214 ELISA positive animals gave CFT titres ≥ 1/10. The highest sensitivity associated to the ELISA test together with the high duration of detectable levels of circulating anti-C. burnetii antibodies were the reasons for using this technique for epidemiological purposes in the current study. Although ELISA test can fail to detect C. burnetii contact at an individual level , it becomes very useful for studies at the population level like the one presented herein. On the other hand, molecular methods are highly sensitive tools for detecting C. burnetii infected animals. Nonetheless, the high variability of C. burnetii excretion by animals throughout the year limits the reliability of molecular methods for epidemiological purposes, especially if sampling takes place outside of the reproductive season.
The seroprevalence found in sheep was comparable to that reported in other Spanish regions where seroprevalence ranged between 1.7% and 18.8%  or in some Mediterranean regions, with values between 9% and 25% [19, 22, 24, 37, 38]. These data highlight the risk of C. burnetii zoonosis associated to sheep in all the Mediterranean countries. Nevertheless, seroprevalence of cattle and goats in some of these countries suggest that these species would also represent a potential risk. In fact, cattle seropositivity ranged between 5.8% and 25% [24, 37], and in goats between 13% and 51% [19, 24, 38]. In Spain, the highest prevalences found in these species were 66.9% for cattle and 32.7% for goats in different production systems from central and southern Spain, respectively , and more recently, 35% of southern Spanish cattle in extensive production have been found to have contact with C. burnetii .
The lower seroprevalence observed in the present study in cattle and goats could be explained by the semi-extensive management conditions in which animals are moving during part of the year in large land surfaces thus reducing the contact between animals. Therefore, the different prevalences of C. burnetii in livestock suggest that local productive system and management factors might influence the life cycle of C. burnetii. Moreover, wildlife could play a relevant role as reservoir for livestock , especially where extensive productive systems are predominant, which increases the risk of wildlife/livestock contact. The significantly higher seroprevalence observed in sheep with regard to beef cattle could not be explained by differences in the sampling dates in relation to the lambing/calving season. Both beef cattle and sheep were surveyed coinciding with the end of the gestation period, when the excretion of C. burnetii by infected animals is higher because of parturition . Interestingly, when CFT was analysed in ELISA positive animals, beef cattle had a higher percentage of reactors (14.3%) compared to sheep (4.9%) indicating a higher number of latent infections in cattle than in sheep. Nevertheless, the small size of the sample and the concentration of CFT-positive animals in a reduced number of herds make it difficult to reach a definitive explanation. Other management factors, like closer contact among ewes during milking, which implies overnight housing, could be the reason for a higher overall ELISA seroprevalence in sheep than in cattle.
Age-related C. burnetii serological patterns have been seldom reported in the scientific literature in regard to domestic ruminants [24, 34]. Pathogen contact rate tends to increase with age simply as a consequence of a higher probability of contact with life span, a feature that herein was observed for sheep and goats.
Long-time contact with C. burnetii in the surveyed herds together with the random selection of sampled animals could explain the lack of association found between herd seroprevalence and abortion reports. Different results have been reported in this regard, with significant associations between seroprevalence and abortion reported for cattle and sheep in several studies [16, 37], whereas in other reports infection with C. burnetii in cattle did not result in abortion, suggesting that infection sometimes can pass unnoticed . In the current study, in 6 cattle herds without reproductive problems within-herd seroprevalence by ELISA ranged between 6.6 and 53% and in 2 of these herds several animals had CFT titers ≥ 1/10 indicating a recent contact with C. burnetii. Although several farmers did not report abortion or reproductive problems, high seroprevalences can be associated with the presence of C. burnetii in the herd. Similarly, Astobiza et al.  found a high within-flock seroprevalence (54%) and a high percentage of C. burnetii shedders at lambing (55-79%) in a sheep flock with a low rate of abortion (3.4%). These observations indicate that there are several epidemiological and clinical aspects of C. burnetii infection that need to be elucidated and require further investigation.
The results reported herein showed that sheep had the highest contact rate with C. burnetii in the region, but also that cattle and goats should not be neglected as part of the domestic cycle of C. burnetii. Based on our observations, we can conclude that measures are to be implemented for the control of C. burnetii and Q fever in the study region along the line of those currently in operation in other European countries. Moreover, further epidemiological research on herd, local and regional factors influencing C. burnetii life cycle is needed in order to establish more efficient control measures that prevent spread of the infection and its associated effects on livestock and humans. At present, a control programme based on vaccination using a Phase I vaccine is in progress and its efficacy will be assessed in the near future.
We acknowledge the collaboration of farmers from the different Breed Farmers Associations. This work was supported by funding from INIA (FAU2006-00002-C04-01), FEDER, and the Department of Agriculture, Fisheries and Food of the Basque Government. F. Ruiz-Fons is supported by a research contract from the 'Instituto de Salud Carlos III' of the Spanish Ministry for Health.
- Maurin M, Raoult D: Q fever. Clin Microbiol Rev. 1999, 12: 518-553.PubMed CentralPubMedGoogle Scholar
- Lapointe JM, Gulland FM, Haines DM, Barr BC, Duignan PJ: Placentitis due to Coxiella burnetii in a Pacific harbour seal (Phoca vitulina richardsi). J Vet Diagn Invest. 1999, 11: 541-543.PubMedView ArticleGoogle Scholar
- Arricau-Bouvery N, Rodolakis A: Is Q Fever an emerging or re-emerging zoonosis?. Vet Res. 2005, 36: 327-349. 10.1051/vetres:2005010.PubMedView ArticleGoogle Scholar
- Kovácová E, Kazar J: Q fever--still a query and underestimated infectious disease. Acta Virol. 2002, 46: 193-210.PubMedGoogle Scholar
- Pascual-Velasco F: [Fiebre Q]. Zamora: Junta de Castilla y León Press 1996.Google Scholar
- Bolaños M, Santana OE, Pérez-Arellano JL, Ángel-Moreno A, Moreno G, Burgazzoli JL, Martín-Sánchez AM: Q fever in Gran Canaria: 40 new cases. Enferm Infecc Microbiol Clin. 2003, 21: 20-23. 10.1157/13042133.PubMedView ArticleGoogle Scholar
- Cardenosa N, Sanfeliu I, Font B, Muñoz T, Nogueras MM, Segura F: Short report: seroprevalence of human infection by Coxiella burnetii in Barcelona (northeast of Spain). Am J Trop Med Hyg. 2006, 75: 33-35.PubMedGoogle Scholar
- Sobradillo V, Ansola P, Baranda F, Corral C: Q fever pneumonia: a review of 164 community-acquired cases in the Basque country. Eur Respir J. 1989, 2: 263-266.PubMedGoogle Scholar
- Lang GH: Coxiellosis (Q fever) in animals. Q fever: The disease. Edited by: Marrie TJ. Boca Raton: CRC Press, 1990, 1: 24-42.Google Scholar
- Woldehiwet Z: Q fever (coxiellosis): epidemiology and pathogenesis. Res Vet Sci. 2004, 77: 93-100. 10.1016/j.rvsc.2003.09.001.PubMedView ArticleGoogle Scholar
- Rodolakis A, Berri M, Hechard C, Caudron C, Souriau A, Bodier CC, Blanchard B, Camuset P, Devillechaise P, Natorp JC, Vadet JP, Arricau-Bouvery N: Comparison of Coxiella burnetii shedding in milk of dairy bovine, caprine, and ovine herds. J Dairy Sci. 2007, 90: 5352-5360. 10.3168/jds.2006-815.PubMedView ArticleGoogle Scholar
- Astobiza I, Barandika JF, Hurtado A, Juste RA, García-Pérez AL: Kinetics of Coxiella burnetiiexcretion in a commercial dairy sheep flock after treatment with oxytetracycline. Vet J.Google Scholar
- Oporto B, Barandika JF, Hurtado A, Adúriz G, Moreno B, García-Pérez AL: Incidence of ovine abortion by Coxiella burnetii in northern Spain. Ann N Y Acad Sci. 2006, 1078: 498-501. 10.1196/annals.1374.095.PubMedView ArticleGoogle Scholar
- Perugini AG, Capuano F, Esposito A, Marianelli C, Martucciello A, Iovane G, Galiero G: Detection of Coxiella burnetii in buffaloes aborted fetuses by IS111 DNA amplification: A preliminary report. Res Vet Sci. 2009, 87: 189-191. 10.1016/j.rvsc.2009.01.005.PubMedView ArticleGoogle Scholar
- To H, Htwe KK, Kako N, Kim HJ, Yamaguchi T, Fukushi H, Hirai K: Prevalence of Coxiella burnetii infection in dairy cattle with reproductive disorders. J Vet Med Sci. 1998, 60: 859-861. 10.1292/jvms.60.859.PubMedView ArticleGoogle Scholar
- Cabassi CS, Taddei S, Donofrio G, Ghidini F, Piancastelli C, Flammini CF, Cavirani S: Association between Coxiella burnetii seropositivity and abortion in dairy cattle of Northern Italy. New Microbiol. 2006, 29: 211-214.PubMedGoogle Scholar
- Kim WJ, Hahn TW, Kim DY, Lee MG, Jung KS, Ogawa M, Kishimoto T, Lee ME, Lee SJ: Seroprevalence of Coxiella burnetii infection in dairy cattle and non-symptomatic people for routine health screening in Korea. J Korean Med Sci. 2006, 21: 823-826. 10.3346/jkms.2006.21.5.823.PubMed CentralPubMedView ArticleGoogle Scholar
- Hatchette TF, Hudson RC, Schlech WF, Campbell NA, Hatchette JE, Ratnam S, Raoult D, Donovan C, Marrie TJ: Goat-associated Q fever: a new disease in Newfoundland. Emerg Infect Dis. 2001, 7: 413-419.PubMed CentralPubMedView ArticleGoogle Scholar
- Loukaides F, Hadjichristodoulou C, Soteriades ES, Kolonia V, Ioannidou MC, Psaroulaki A, Tselentis Y: Active surveillance of Q fever in human and animal population of Cyprus. BMC Infect Dis. 2006, 6: 48-10.1186/1471-2334-6-48.PubMed CentralPubMedView ArticleGoogle Scholar
- Hellenbrand W, Breuer T, Petersen L: Changing epidemiology of Q fever in Germany, 1947-1999. Emerg Infect Dis. 2001, 7: 789-796. 10.3201/eid0705.010504.PubMed CentralPubMedView ArticleGoogle Scholar
- Tissot-Dupont H, Amadei MA, Nezri M, Raoult D: Wind in November, Q fever in December. Emerg Infect Dis. 2004, 10: 1264-1269.PubMed CentralPubMedView ArticleGoogle Scholar
- Kennerman E, Rousset E, Gölcü E, Dufour P: Seroprevalence of Q fever (coxiellosis) in sheep from the southern Marmara Region, Turkey. Comp Immunol Microbiol Infect Dis. 2010, 33: 37-45. 10.1016/j.cimid.2008.07.007.PubMedView ArticleGoogle Scholar
- Hatchette T, Campbell N, Whitney H, Hudson R, Marrie TJ: Seroprevalence of Coxiella burnetii in selected populations of domestic ruminants in Newfoundland. Can Vet J. 2002, 43: 363-364.PubMed CentralPubMedGoogle Scholar
- Psaroulaki A, Hadjichristodoulou C, Loukaides F, Soteriades E, Konstantinidis A, Papastergiou P, Ioannidou MC, Tselentis Y: Epidemiological study of Q fever in humans, ruminant animals, and ticks in Cyprus using a geographical information system. Eur J Clin Microbiol Infect Dis. 2006, 25: 576-586. 10.1007/s10096-006-0170-7.PubMedView ArticleGoogle Scholar
- Çekani M, Papa A, Kota M, Velo E, Berxholi K: Report of a serological study of Coxiella burnetii in domestic animals in Albania. Vet J. 2008, 175: 276-278. 10.1016/j.tvjl.2007.01.005.PubMedView ArticleGoogle Scholar
- Capuano F, Landolfi MC, Monetti DM: Influence of three types of farm management on the seroprevalence of Q fever as assessed by an indirect immunofluorescence assay. Vet Rec. 2001, 149: 669-671.PubMedView ArticleGoogle Scholar
- Ruiz-Fons F, Rodriguez O, Torina A, Naranjo V, Gortázar C, de la Fuente J: Prevalence of Coxiella burnetti infection in wild and farmed ungulates. Vet Microbiol. 2008, 126: 282-286. 10.1016/j.vetmic.2007.06.020.PubMedView ArticleGoogle Scholar
- Eustat: Basque Statistics Institute. [http://www.eustat.es/bancopx/spanish/Economía/Sector%20primario/Censo%20agrario/Ganadería/Ganadería.html]
- World Organization for Animal Health. [http://www.oie.int/eng/normes/mmanual/2008/pdf/2.01.12_Q-FEVER.pdf]
- Rogan WJ, Gladen B: Estimating prevalence from the results of a screening test. Am J Epidemiol. 1978, 107: 71-76.PubMedGoogle Scholar
- Martin SW, Meek AH, Willeberg P: Veterinary Epidemiology. Measures of disease frequency. Ames: Iowa State University Press 1987.Google Scholar
- Sanzo JM, García MA, Sáez MP, Sarobe V, Audikana A, Dehesa V: [Fiebre Q]. Vitoria-Gasteiz: Servicio Central de Publicaciones del Gobierno Vasco Press 1991.Google Scholar
- Montes M, Cilla G, Vicente D, Nieto D, Ercibengoa M, Pérez-Trallero E: Gipuzkoa, Basque Country, Spain (1984-2004): A hyperendemic area of Q fever. Hospital Donostia. Ann N Y Acad Sci. 2006, 1078: 129-132. 10.1196/annals.1374.020.PubMedView ArticleGoogle Scholar
- García-Pérez AL, Astobiza I, Barandika JF, Atxaerandio R, Hurtado A, Juste RA: Investigation of Coxiella burnetii occurrence in dairy sheep flocks by bulk-tank milk analysis and antibody levels determination. J Dairy Sci. 2009, 92: 1581-1584. 10.3168/jds.2008-1672.PubMedView ArticleGoogle Scholar
- Kovácová E, Kazar J, Spanelova D: Suitability of various Coxiella burnetii antigen preparations for detection of serum antibodies by various tests. Acta Virol. 1998, 42: 365-368.PubMedGoogle Scholar
- Rousset E, Durand B, Berri M, Dufour P, Prigent M, Russo P, Delcroix T, Touratier A, Rodolakis A, Aubert M: Comparative diagnostic potential of three serological tests for abortive Q fever in goat herds. Vet Microbiol. 2007, 124: 286-297. 10.1016/j.vetmic.2007.04.033.PubMedView ArticleGoogle Scholar
- Cetinkaya B, Kalender H, Ertas HB, Muz A, Arslan N, Ongor H, Gurcay M: Seroprevalence of coxiellosis in cattle, sheep and people in the east of Turkey. Vet Rec. 2000, 146: 131-136.PubMedView ArticleGoogle Scholar
- Masala G, Porcu R, Sanna G, Chessa G, Cillara G, Chisu V, Tola S: Occurrence, distribution, and role in abortion of Coxiella burnetii in sheep and goats in Sardinia, Italy. Vet Microbiol. 2004, 99: 301-305. 10.1016/j.vetmic.2004.01.006.PubMedView ArticleGoogle Scholar
- Paiba GA, Lloyd G, Bewley K, Webster GJ, Green LE, Morgan KL: An investigaton of Coxiella burnetii infection at calving within a herd of dairy cows in England using PCR. Rickettsiae and rickettsial diseases at the turn of the third millennium. Edited by: Brouqui P, Raoult D. Amsterdam: Elsevier, 1999:387-392.Google Scholar
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